/* ---------------------------------------------------------------------- 
* Copyright (C) 2010 ARM Limited. All rights reserved.   
*  
* $Date:        29. November 2010  
* $Revision: 	V1.0.3
*  
* Project: 	    CMSIS DSP Library  
* Title:	    arm_signal_converge_example_f32.c		  
*  
* Description:	Example code demonstrating convergence of an adaptive 
*               filter. 
* 
* Target Processor: Cortex-M4/Cortex-M3  
*
*
* Version 1.0.3 2010/11/29 
*    Re-organized the CMSIS folders and updated documentation. 
* 
* Version 1.0.1 2010/10/05 KK 
*    Production release and review comments incorporated.  
*
* Version 1.0.0 2010/09/20 KK
*    Production release and review comments incorporated.
* ------------------------------------------------------------------- */ 
 
/** 
 * @ingroup groupExamples 
 */ 
 
/**    
 * @defgroup SignalConvergence Signal Convergence Example    
 * 
 * \par Description: 
 * \par
 * Demonstrates the ability of an adaptive filter to "learn" the transfer function of 
 * a FIR lowpass filter using the Normalized LMS Filter, Finite Impulse 
 * Response (FIR) Filter, and Basic Math Functions.
 * 
 * \par Algorithm:
 * \par
 * The figure below illustrates the signal flow in this example. Uniformly distributed white 
 * noise is passed through an FIR lowpass filter. The output of the FIR filter serves as the 
 * reference input of the adaptive filter (normalized LMS filter). The white noise is input 
 * to the adaptive filter. The adaptive filter learns the transfer function of the FIR filter.
 * The filter outputs two signals: (1) the output of the internal adaptive FIR filter, and 
 * (2) the error signal which is the difference between the adaptive filter and the reference 
 * output of the FIR filter. Over time as the adaptive filter learns the transfer function 
 * of the FIR filter, the first output approaches the reference output of the FIR filter,
 * and the error signal approaches zero. 
 * \par
 * The adaptive filter converges properly even if the input signal has a large dynamic 
 * range (i.e., varies from small to large values). The coefficients of the adaptive filter 
 * are initially zero, and then converge over 1536 samples. The internal function test_signal_converge() 
 * implements the stopping condition. The function checks if all of the values of the error signal have a 
 * magnitude below a threshold DELTA. 
 * 
 * \par Block Diagram:
 * \par
 * \image html SignalFlow.gif 
 *
 *
 * \par Variables Description:
 * \par
 * \li \c testInput_f32 points to the input data
 * \li \c firStateF32 points to FIR state buffer
 * \li \c lmsStateF32 points to Normalised Least mean square FIR filter state buffer
 * \li \c FIRCoeff_f32 points to coefficient buffer
 * \li \c lmsNormCoeff_f32 points to Normalised Least mean square FIR filter coefficient buffer
 * \li \c wire1, wir2, wire3 temporary buffers
 * \li \c errOutput, err_signal temporary error buffers 
 *
 * \par CMSIS DSP Software Library Functions Used:
 * \par
 * - arm_lms_norm_init_f32()
 * - arm_fir_init_f32()
 * - arm_fir_f32()
 * - arm_lms_norm_f32()
 * - arm_scale_f32()
 * - arm_abs_f32()
 * - arm_sub_f32()
 * - arm_min_f32()
 * - arm_copy_f32()
 *
 * <b> Refer  </b> 
 * \link arm_signal_converge_example_f32.c \endlink
 * 
 */  
 
 
/** \example arm_signal_converge_example_f32.c 
  */  
     
#include "arm_math.h" 
#include "math_helper.h" 
 
/* ---------------------------------------------------------------------- 
** Global defines for the simulation 
* ------------------------------------------------------------------- */ 
 
#define TEST_LENGTH_SAMPLES 1536 
#define NUMTAPS 			32 
#define BLOCKSIZE 			32 
#define DELTA_ERROR         0.000001f 
#define DELTA_COEFF         0.0001f 
#define MU 					0.5f 
 
#define NUMFRAMES (TEST_LENGTH_SAMPLES / BLOCKSIZE) 
 
/* ---------------------------------------------------------------------- 
* Declare FIR state buffers and structure  
* ------------------------------------------------------------------- */ 
  
float32_t firStateF32[NUMTAPS + BLOCKSIZE];  
arm_fir_instance_f32 LPF_instance; 
 
/* ---------------------------------------------------------------------- 
* Declare LMSNorm state buffers and structure  
* ------------------------------------------------------------------- */ 
  
float32_t lmsStateF32[NUMTAPS + BLOCKSIZE];  
float32_t errOutput[TEST_LENGTH_SAMPLES]; 
arm_lms_norm_instance_f32 lmsNorm_instance; 
 
 
/* ---------------------------------------------------------------------- 
* Function Declarations for Signal Convergence Example  
* ------------------------------------------------------------------- */ 
 
arm_status test_signal_converge_example( void ); 
 
 
/* ---------------------------------------------------------------------- 
* Internal functions 
* ------------------------------------------------------------------- */ 
arm_status test_signal_converge(float32_t* err_signal, 
			       			     uint32_t blockSize); 
 
void getinput(float32_t* input, 
		 uint32_t fr_cnt,  
   	     uint32_t blockSize);  
 
/* ---------------------------------------------------------------------- 
* External Declarations for FIR F32 module Test 
* ------------------------------------------------------------------- */ 
extern float32_t testInput_f32[TEST_LENGTH_SAMPLES]; 
extern float32_t lmsNormCoeff_f32[32]; 
extern const float32_t FIRCoeff_f32[32]; 
extern arm_lms_norm_instance_f32 lmsNorm_instance; 
 
/* ---------------------------------------------------------------------- 
* Declare I/O buffers  
* ------------------------------------------------------------------- */ 
 
float32_t wire1[BLOCKSIZE]; 
float32_t wire2[BLOCKSIZE]; 
float32_t wire3[BLOCKSIZE]; 
float32_t err_signal[BLOCKSIZE]; 
 
/* ---------------------------------------------------------------------- 
* Signal converge test 
* ------------------------------------------------------------------- */ 
 
int32_t main(void) 
{ 
  uint32_t i; 
  arm_status status; 
  uint32_t index; 
  float32_t minValue; 
 
  /* Initialize the LMSNorm data structure */ 
  arm_lms_norm_init_f32(&lmsNorm_instance, NUMTAPS, lmsNormCoeff_f32, lmsStateF32, MU, BLOCKSIZE); 
 
  /* Initialize the FIR data structure */ 
  arm_fir_init_f32(&LPF_instance, NUMTAPS, (float32_t *)FIRCoeff_f32, firStateF32, BLOCKSIZE); 
 
  /* ---------------------------------------------------------------------- 
  * Loop over the frames of data and execute each of the processing 
  * functions in the system. 
  * ------------------------------------------------------------------- */ 
 
  for(i=0; i < NUMFRAMES; i++)  
    { 
      /* Read the input data - uniformly distributed random noise - into wire1 */  
      arm_copy_f32(testInput_f32 + (i * BLOCKSIZE), wire1, BLOCKSIZE); 
 
      /* Execute the FIR processing function.  Input wire1 and output wire2 */  
      arm_fir_f32(&LPF_instance, wire1, wire2, BLOCKSIZE); 
       
      /* Execute the LMS Norm processing function*/  
 
      arm_lms_norm_f32(&lmsNorm_instance, /* LMSNorm instance */ 
		       wire1,                     /* Input signal */  
		       wire2,			          /* Reference Signal */ 
		       wire3, 			          /* Converged Signal */ 
		       err_signal, 		          /* Error Signal, this will become small as the signal converges */ 
		       BLOCKSIZE);		          /* BlockSize */ 
 
      /* apply overall gain */  
      arm_scale_f32(wire3, 5, wire3, BLOCKSIZE);	 /* in-place buffer */  
    } 
 
  status = ARM_MATH_SUCCESS; 
 
  /* ------------------------------------------------------------------------------- 
  * Test whether the error signal has reached towards 0. 
  * ----------------------------------------------------------------------------- */ 
 
  arm_abs_f32(err_signal, err_signal, BLOCKSIZE); 
  arm_min_f32(err_signal, BLOCKSIZE, &minValue, &index); 
 
  if (minValue > DELTA_ERROR) 
  { 
      status = ARM_MATH_TEST_FAILURE; 
  } 
 
  /* ---------------------------------------------------------------------- 
  * Test whether the filter coefficients have converged. 
  * ------------------------------------------------------------------- */ 
 
  arm_sub_f32((float32_t *)FIRCoeff_f32, lmsNormCoeff_f32, lmsNormCoeff_f32, NUMTAPS); 
 
  arm_abs_f32(lmsNormCoeff_f32, lmsNormCoeff_f32, NUMTAPS); 
  arm_min_f32(lmsNormCoeff_f32, NUMTAPS, &minValue, &index); 
 
  if (minValue > DELTA_COEFF) 
  { 
      status = ARM_MATH_TEST_FAILURE; 
  } 
 
  /* ---------------------------------------------------------------------- 
  * Loop here if the signals did not pass the convergence check. 
  * This denotes a test failure 
  * ------------------------------------------------------------------- */ 
 
  if( status != ARM_MATH_SUCCESS) 
  { 
      while(1); 
  } 

    while(1);                             /* main function does not return */
} 
 
 /** \endlink */ 
		 
 
		 
